Summary of Study ST002301

This data is available at the NIH Common Fund's National Metabolomics Data Repository (NMDR) website, the Metabolomics Workbench, https://www.metabolomicsworkbench.org, where it has been assigned Project ID PR001474. The data can be accessed directly via it's Project DOI: 10.21228/M86998 This work is supported by NIH grant, U2C- DK119886.

See: https://www.metabolomicsworkbench.org/about/howtocite.php

This study contains a large results data set and is not available in the mwTab file. It is only available for download via FTP as data file(s) here.

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Study IDST002301
Study TitleSerum metabolomics profiling identifies new predictive biomarkers for disease severity in COVID-19 patients
Study SummaryOver the last three years, numerous groups have reported on different predictive models of disease severity in COVID-19 patients. However, almost all such models, which relied on serum biomarkers, clinical data or a combination of both, were subsequently deemed as cumbersome, inadequate and/or subject to bias. Moreover, although serum metabolomics profiling has shown significant differences among patients with different degrees of disease severity, the use of serum metabolomics profiling to identify prognostic biomarkers has, so far, been neglected. Herein, we sought to develop highly predictive models of disease severity by integrating routine laboratory findings and serum metabolomics profiling which identified several metabolites including K_4_aminophenol, acetaminophen and cytosine as potential biomarkers of disease severity in COVID-19 patients. Two models were subsequently developed and internally validated on the basis of ROC-AUC values. The predictive accuracy of the first model was 0.998 (95% CI: 0.992 to 1.000) with an optimal cut-off risk score of 4 biomarkers from among 8 linearly-related biomarkers (D-dimer, ferritin, neutrophil counts, Hp, sTfR, K_4_aminophenol, acetaminophen and cytosine). The predictive accuracy of the second model was 0.996 (95% CI: 0.989 to 1.000) with an optimal cut-off risk score of 3 biomarkers from among 6 biomarkers (D-dimer, ferritin, neutrophil counts, Hp, sTfR and cytosine). The two models are of high predictive power, need a small number of variables that can be acquired at minimal cost and effort, and can be applied independent of non-empirical clinical data. In conclusion, the metabolomics profiling data and the modeling work stemming from it, as presented here, could further explain the cause of COVID-19 disease prognosis and patient management.
Institute
Sharjah Institute for Medical Research
Last NameSoares
First NameNelson
AddressM32, SIMR, College of Pharmacy, Health Sciences, University of Sharjah, Sharjah, UAE, Sharjah, 000, United Arab Emirates
Emailnsoares@sharjah.ac.ae
Phone+971501594048
Submit Date2022-09-21
Raw Data AvailableYes
Raw Data File Type(s)d
Analysis Type DetailLC-MS
Release Date2023-03-01
Release Version1
Nelson Soares Nelson Soares
https://dx.doi.org/10.21228/M86998
ftp://www.metabolomicsworkbench.org/Studies/ application/zip

Select appropriate tab below to view additional metadata details:

Project:

Project ID:PR001474
Project DOI:doi: 10.21228/M86998
Project Title:Serum metabolomics profiling identifies new predictive biomarkers for disease severity in COVID-19 patients
Project Summary:Over the last three years, numerous groups have reported on different predictive models of disease severity in COVID-19 patients. However, almost all such models, which relied on serum biomarkers, clinical data or a combination of both, were subsequently deemed as cumbersome, inadequate and/or subject to bias. Moreover, although serum metabolomics profiling has shown significant differences among patients with different degrees of disease severity, the use of serum metabolomics profiling to identify prognostic biomarkers has, so far, been neglected. Herein, we sought to develop highly predictive models of disease severity by integrating routine laboratory findings and serum metabolomics profiling which identified several metabolites including K_4_aminophenol, acetaminophen and cytosine as potential biomarkers of disease severity in COVID-19 patients. Two models were subsequently developed and internally validated on the basis of ROC-AUC values. The predictive accuracy of the first model was 0.998 (95% CI: 0.992 to 1.000) with an optimal cut-off risk score of 4 biomarkers from among 8 linearly-related biomarkers (D-dimer, ferritin, neutrophil counts, Hp, sTfR, K_4_aminophenol, acetaminophen and cytosine). The predictive accuracy of the second model was 0.996 (95% CI: 0.989 to 1.000) with an optimal cut-off risk score of 3 biomarkers from among 6 biomarkers (D-dimer, ferritin, neutrophil counts, Hp, sTfR and cytosine). The two models are of high predictive power, need a small number of variables that can be acquired at minimal cost and effort, and can be applied independent of non-empirical clinical data. In conclusion, the metabolomics profiling data and the modeling work stemming from it, as presented here, could further explain the cause of COVID-19 disease prognosis and patient management.
Institute:Sharjah Institute for Medical Research
Last Name:Soares
First Name:Nelson
Address:M32, SIMR, College of Pharmacy, Health Sciences, University of Sharjah, Sharjah, UAE, Sharjah, 000, United Arab Emirates
Email:nsoares@sharjah.ac.ae
Phone:+971 50 159 4048

Subject:

Subject ID:SU002387
Subject Type:Human
Subject Species:Homo sapiens
Taxonomy ID:9606

Factors:

Subject type: Human; Subject species: Homo sapiens (Factor headings shown in green)

mb_sample_id local_sample_id Severity of Disease
SA226414Plasma45-02_51_1_2375Asymptomatic
SA226415Plasma46-01_52_1_2376Asymptomatic
SA226416Plasma45-01_51_1_2374Asymptomatic
SA226417Plasma44-01_50_1_2372Asymptomatic
SA226418Plasma43-01_49_1_2370Asymptomatic
SA226419Plasma46-02_52_1_2377Asymptomatic
SA226420Plasma44-02_50_1_2373Asymptomatic
SA226421Plasma47-01_53_1_2378Asymptomatic
SA226422Plasma49-01_55_1_2382Asymptomatic
SA226423Plasma49-02_55_1_2383Asymptomatic
SA226424Plasma48-02_54_1_2381Asymptomatic
SA226425Plasma48-01_54_1_2380Asymptomatic
SA226426Plasma47-02_53_1_2379Asymptomatic
SA226427Plasma42-02_48_1_2369Asymptomatic
SA226428Plasma41-02_47_1_2357Asymptomatic
SA226429Plasma37-02_43_1_2349Asymptomatic
SA226430Plasma38-01_44_1_2350Asymptomatic
SA226431Plasma37-01_43_1_2348Asymptomatic
SA226432Plasma36-02_42_1_2347Asymptomatic
SA226433Plasma35-02_41_1_2345Asymptomatic
SA226434Plasma36-01_42_1_2346Asymptomatic
SA226435Plasma38-02_44_1_2351Asymptomatic
SA226436Plasma39-01_45_1_2352Asymptomatic
SA226437Plasma41-01_47_1_2356Asymptomatic
SA226438Plasma50-01_56_1_2384Asymptomatic
SA226439Plasma40-02_46_1_2355Asymptomatic
SA226440Plasma40-01_46_1_2354Asymptomatic
SA226441Plasma39-02_45_1_2353Asymptomatic
SA226442Plasma42-01_48_1_2368Asymptomatic
SA226443Plasma51-01_57_1_2386Asymptomatic
SA226444Plasma60-02_66_1_2409Asymptomatic
SA226445Plasma61-01_67_1_2410Asymptomatic
SA226446Plasma60-01_66_1_2408Asymptomatic
SA226447Plasma59-02_65_1_2407Asymptomatic
SA226448Plasma58-02_64_1_2405Asymptomatic
SA226449Plasma59-01_65_1_2406Asymptomatic
SA226450Plasma61-02_67_1_2411Asymptomatic
SA226451Plasma62-01_68_1_2412Asymptomatic
SA226452Plasma64-01_70_1_2416Asymptomatic
SA226453Plasma64-02_70_1_2417Asymptomatic
SA226454Plasma63-02_69_1_2415Asymptomatic
SA226455Plasma63-01_69_1_2414Asymptomatic
SA226456Plasma62-02_68_1_2413Asymptomatic
SA226457Plasma58-01_64_1_2404Asymptomatic
SA226458Plasma57-02_63_1_2403Asymptomatic
SA226459Plasma53-01_59_1_2390Asymptomatic
SA226460Plasma53-02_59_1_2391Asymptomatic
SA226461Plasma52-02_58_1_2389Asymptomatic
SA226462Plasma52-01_58_1_2388Asymptomatic
SA226463Plasma35-01_41_1_2344Asymptomatic
SA226464Plasma51-02_57_1_2387Asymptomatic
SA226465Plasma54-01_60_1_2392Asymptomatic
SA226466Plasma54-02_60_1_2393Asymptomatic
SA226467Plasma56-02_62_1_2401Asymptomatic
SA226468Plasma57-01_63_1_2402Asymptomatic
SA226469Plasma56-01_62_1_2400Asymptomatic
SA226470Plasma55-02_61_1_2395Asymptomatic
SA226471Plasma55-01_61_1_2394Asymptomatic
SA226472Plasma50-02_56_1_2385Asymptomatic
SA226473Plasma43-02_49_1_2371Asymptomatic
SA226474Plasma13-02_19_1_2297Mild
SA226475Plasma13-01_19_1_2296Mild
SA226476Plasma12-02_18_1_2295Mild
SA226477Plasma14-01_20_1_2298Mild
SA226478Plasma14-02_20_1_2299Mild
SA226479Plasma16-01_22_1_2302Mild
SA226480Plasma15-02_21_1_2301Mild
SA226481Plasma15-01_21_1_2300Mild
SA226482Plasma12-01_18_1_2294Mild
SA226483Plasma11-02_17_1_2293Mild
SA226484Plasma08-02_14_1_2287Mild
SA226485Plasma02-02_8_1_2275Mild
SA226486Plasma02-01_8_1_2274Mild
SA226487Plasma09-01_15_1_2288Mild
SA226488Plasma09-02_15_1_2289Mild
SA226489Plasma11-01_17_1_2292Mild
SA226490Plasma10-02_16_1_2291Mild
SA226491Plasma10-01_16_1_2290Mild
SA226492Plasma16-02_22_1_2303Mild
SA226493Plasma08-01_14_1_2286Mild
SA226494Plasma71-02_77_1_2431Severe
SA226495Plasma71-01_77_1_2430Severe
SA226496Plasma70-02_76_1_2429Severe
SA226497Plasma70-01_76_1_2428Severe
SA226498Plasma72-01_78_1_2432Severe
SA226499Plasma72-02_78_1_2433Severe
SA226500Plasma74-02_80_1_2437Severe
SA226501Plasma74-01_80_1_2436Severe
SA226502Plasma73-02_79_1_2435Severe
SA226503Plasma73-01_79_1_2434Severe
SA226504Plasma69-02_75_1_2427Severe
SA226505Plasma69-01_75_1_2426Severe
SA226506Plasma66-01_72_1_2420Severe
SA226507Plasma65-02_71_1_2419Severe
SA226508Plasma65-01_71_1_2418Severe
SA226509Plasma32-01_38_1_2338Severe
SA226510Plasma66-02_72_1_2421Severe
SA226511Plasma67-01_73_1_2422Severe
SA226512Plasma68-02_74_1_2425Severe
SA226513Plasma68-01_74_1_2424Severe
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Collection:

Collection ID:CO002380
Collection Summary:In this retrospective cohort study, blood samples were collected from donors who tested positive for COVID-19 and presented with no, mild or severe symptoms between March 20 until July 17, 2020. Patients were diagnosed with COVID-19 using a nasal swab PCR test and later divided into three groups (asymptomatic, mild, and severe) based on their clinical presentation. Each donor gave a 10 ml blood sample, one half of which was collected in a plain tube and the other half in an EDTA vacutainer. A total of 85 samples were collected (30 COVID-19-positive asymptomatic, 10 COVID-19-positive with mild symptoms, and 45 COVID-19-positive with severe symptoms) for the purpose of this study. COVID-19-positive asymptomatic individuals were identified as a result of the national screening campaigns. Symptomatic COVID-19 patients were classified into mild or severe based on guidelines published by Abu Dhabi Department of Health (circular number 33, 19th April 2020). Patients with mild disease presented with upper respiratory tract infection and symptoms like fever, dry cough, sore throat, runny nose, muscle and joint pains without shortness of breath. Patients with severe disease presented with severe pneumonia and symptoms like fever, cough, dyspnea and fast breathing (>30 per minute), in addition to oxygen saturation <90%. Immediately upon sample collection, the hospital laboratory staff separated and tested the serum for CRP, D-dimer, ferritin, IL-6 and LDH; a complete blood count was also performed on each sample. Whole blood samples were also aliquoted and frozen at −80 0C for subsequent processing and analysis. The study was jointly approved by the Ministry of Health, Abu Dhabi and Dubai Health Authority (DOH/CVDC/2020/1949) on the understanding that samples will be number-coded to hide patient identity, that no personal information will be shared with a third party and that no sample analysis can be performed by entities other than the Research Institute of Medical and Health Sciences (RIMHS), the University of Sharjah (UOS) without prior written approval.
Sample Type:Blood (plasma)

Treatment:

Treatment ID:TR002399
Treatment Summary:No treatment, study examines the predictive ability of metabolomic profiling models to predict covid disease severity

Sample Preparation:

Sampleprep ID:SP002393
Sampleprep Summary:Plasma was obtained after the collection of samples into heparinized tubes followed by centrifugation for 5 minutes (3000g). The samples were stored at –80 ºC for long-term storage until further metabolomics analysis. An aliquot of plasma sample into a microcentrifuge tube and add cold methanol into the sample at 3:1 v/v (i.e., 30 μL sample, add 90 μL cold methanol) vortex and allow to sit in –20ºC for two hrs. Next, centrifuge the samples at 20,817 x g for 15 min at 4ºC. Then, transfer the supernatant to a new microcentrifuge tube. Usually, transfer three times the original sample volume (i.e., for 30 μL sample, add 90 μL cold methanol, then transfer 90 μL supernatant). Dry down the sample using Speed vac at 30 – 40°C. Store the dried sample in a –80ºC freezer for further use or dissolve it in solvent for LC-MS/MS analysis

Combined analysis:

Analysis ID AN003757
Analysis type MS
Chromatography type Reversed phase
Chromatography system Bruker Elute
Column Hamilton Intensity Solo 2 C18
MS Type ESI
MS instrument type QTOF
MS instrument name Bruker timsTOF
Ion Mode POSITIVE
Units AU

Chromatography:

Chromatography ID:CH002780
Instrument Name:Bruker Elute
Column Name:Hamilton Intensity Solo 2 C18
Chromatography Type:Reversed phase

MS:

MS ID:MS003500
Analysis ID:AN003757
Instrument Name:Bruker timsTOF
Instrument Type:QTOF
MS Type:ESI
MS Comments:The ESI source with dry nitrogen gas was 10 L/min, and the drying temperature was equal to 220℃ with nebulizer gas pressure set to 2.2 bar. The capillary voltage of the ESI was 4500 V and the Plate Offset 500 V. MS acquisition scan was set at 20-1300 m/z and the collision energy at 7 eV. Sodium formate was injected as an external calibrant between 0.1 and 0.3 minutes. A total volume of 10 µL sample was injected into the TIMS-TOF MS.
Ion Mode:POSITIVE
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